DNA has an oscillating double-helix structure. This oscillating means that the DNA molecules conduct electricity much less well than was previously thought. Ultrafast cameras were one of the devices the researchers from Amsterdam used to demonstrate this.

It turns out the DNA does not have a rigid regular structure as stated in textbooks. In reality the double helix of DNA forms a very dynamic chaotic system. The rigid structure in textbooks should be regarded as the average position of many structures taken over a period of time.

The Amsterdam researchers showed that the chaotic movements limit the electrical conductivity properties of DNA. Electrical conductivity, even if it is imperfect, is of vital importance for the cell. For example, the cell uses electrons from the charge transfer in DNA to repair damaged bonds.

According to the researchers the electrical conductivity would be much better if DNA had a fixed double-helix structure in which the individual building blocks were neatly stacked on top of each other.

The results have consequences for scientists who are developing new molecular microelectronics. In this sort of experimental electronics the DNA molecules would have to be able to initiate a range of reactions by means of charge transfer. The electronics specialists must now take the inefficient electrical conductivity of DNA into consideration.

The DNA examined by researchers included a piece of DNA with the form of a hair clip. It is similar to an important piece of RNA in the HIV virus. Researchers incorporated fluorescent molecule groups in a very specific manner. They then bombarded the piece of DNA with extremely short laser pulses. A special type of camera registered how the molecule fluoresced.

The experimental set-up of the Amsterdam researchers can observe movements or vibrations which occur in one millionth of a millionth of a second. Or put scientifically the set-up has a resolution of a picosecond. To put this into perspective: normal film cameras take 24 pictures per second and only detect the vibration if it lasts longer than 0.02 seconds.

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Further information can be obtained from Olaf Larsen (Biophysics and Physics of Complex Systems, Free University of Amsterdam), tel. 31-20-422-0903 or 31-62-500-7670 (home), 31-20-444-7426 (work), fax 31-20-444-7999 (work), e-mail olaf@nat.vu.nl and olaf_larsen@hotmail.com. A short film (all rights reserved) about oscillating DNA can be found on the Internet: http://www.nat.vu.nl/n_s_old/vakgroepen/bio/english/research/index4.html.

Contact: Michel Philippens, philippens@nwo.nl, 31-70-344-0784, Netherlands Organization for Scientific Research

Source of the given news and the copyrights belong to a Netherlands Organization for Scientific Research

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